Electrodynamic field strength triggering system

ABSTRACT

Systems and methods for automatically triggering wireless power and data exchange between an external reader and an implanted sensor. The implanted sensor may measure the strength of an electrodynamic field received wirelessly from the reader and convey field strength data based on the measured strength of the received electrodynamic field to the reader. If the field strength data indicates that the strength of an electrodynamic field received by the sensor is sufficient for the implanted sensor to perform an analyte measurement, the reader may convey an analyte measurement command to the sensor, which may execute the analyte measurement command and convey measurement information back to the reader. The systems and methods may trigger the analyte measurement as the reader transiently passes within sufficient range/proximity to the implant (or vice versa).

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.15/430,198, filed on Feb. 10, 2017, which is a continuation of U.S.patent application Ser. No. 13/650,016, filed on Oct. 11, 2012,abandoned, which claims priority to U.S. Provisional Application No.61/545,874, filed on Oct. 11, 2011, and U.S. Provisional Application No.61/597,496, filed on Feb. 10, 2012, all of which are incorporated byreference herein in their entireties.

BACKGROUND Field of the Invention

The present invention relates to a system for obtaining analytemeasurements. Specifically, the present invention relates to an externalreader that can interrogate an implanted analyte sensor.

Description of the Background

In a system in which an external sensor reader provides power to animplanted sensor for operation (e.g., analyte measurement) and datatransfer, the primary coil of the external sensor reader must beappropriately aligned with the secondary coil of the implanted sensor.However, there is a finite and relatively short range (typically lessthan one inch) within which the implanted sensor receives anelectrodynamic field from the external sensor reader of sufficientstrength to power the sensor for analyte measurement and data transfer.In addition, finding the correct alignment is made more difficultbecause an implanted sensor is not visible to the user.

An attached system that physically maintains the external sensor readerin alignment with the implanted sensor using, for example, a fixedwristwatch, armband, or adhesive patch does not work well for users whodo not wish to wear a wristwatch, armband, adhesive patch, or otherfixed system and/or only require intermittent readings from theimplanted sensor during any period in time. Furthermore, even a systemthat enabled on-demand measurement would be unsatisfactory if itrequired a user to probe around either by trial and error or by watchinga field strength meter to find the relative position in space from whichto initiate a reading.

RFID systems and readers are used for animal identification, anti-theftapplications, inventory control, highway toll road tracking, creditcard, and ID cards, but are not applicable in the context of animplantable sensor and external reader system. RFID systems aretransponders, and the energy supplied must only reflect a presetnumerical sequence as an ID. This requires much less power than anactivated remote/implanted sensor, and an RFID system is thereforecapable of much more range because of the extremely low operationalpower requirement from the RFID tag and can allow operation at ranges ofup to 5 feet or more. In contrast, an implanted analyte sensor must beprovided with much more power to operate its circuitry for makingmeasurements and conveying the data to the reader. In fact, transfer ofpower by induction between two coils is very inefficient at distance,and such systems are often limited to approximately one inch or less,instead of multiple feet possible in RFID systems.

A hobby or utility grade metal detector or stud finder is alsoinapplicable in the context of an implanted sensor and external readersystem. Metal detection or stud finding is an example of motion typeoperation, but the relationship between the primary coil and the metalto be detected is completely passive. Thus, in stark contrast with animplanted sensor and external reader system, where the implanted sensorrequires power for activation, measurement, and data transfer, no poweris required to activate the metal being detected by a metal detector orstud finder, and only the relative motion perturbation of theelectromagnetic field is required.

Accordingly, there is a need for an improved implanted sensor andexternal reader system.

SUMMARY

One aspect of the invention is a triggering mechanism thattriggers/initiates an analyte reading/measurement from an implantablesensor (e.g., an implantable chemical or biochemical sensor) as anexternal reader transiently passes within sufficient range/proximity tothe implant (or vice versa). The movement may be relative movement (a)between a stationary implant and a transient reader, (b) between astationary reader and a transient implant site (e.g., relative movementof a wrist implant site into and/or out of a stationary coil), or (c)relative movement between both. In some embodiments, the triggeringmechanism automatically triggers the system to take a reading from thesensor at just the moment when relative movement of a handheld readerand the sensor has placed the reader within sufficient field strengthrange of the sensor without the user needing to probe around either bytrial and error or by watching a field strength meter to find therelative position in space from which to initiate a reading. In oneembodiment, the invention may automate the analyte measurement sequenceand reduce the action required by the user to nothing more than movementof a handheld sensor reader.

One aspect of the invention includes a circuitry component that takesmeasurements of a current proportional to the field strength received bythe sensor, and that indicates the relative field strength (current) ormagnetic coupling between the primary coil of the reader and thesecondary coil within the sensor. In some embodiments, the systemdetects when the sensor is within range to allow the power and datatransfer and immediately sends a command within the reader to initiatethe power transfer and data receiving sequence. In some embodiments,because the reading/measurement happens very fast between a sensor andreader (e.g., on the order of 10 milliseconds), the relative movementmay be dynamic as relative swipe-type hand movements.

One aspect of the present invention allows either retro add-on typeadaptation of reader capable platforms (e.g., smart phones) orintegrated inclusion in new design of smart phones, handhelds, dedicatedsensor readers, or other compatible electronic devices. In someembodiments, the present invention may enable intermittent readings tobe taken automatically from an implantable sensor under the relativemotion of the external sensor reader and sensor/implant site intoclose-enough proximity.

One embodiment of the invention is implemented by (i) taking a measurewithin a circuitry that contains a value (e.g., current) proportional tofield strength; (ii) when that value reaches a threshold value of fieldstrength coupling between the two coils of a reader-sensor pair,indicating that reliable power and data transfer can occur; and (iii)triggering the regular read command sequence, which then initiates thereading to be taken by the reader for subsequent display to the user.The reader may then be returned to pocket, or purse, or wherever theuser keeps it until a next reading is desired.

In one aspect, the present invention provides a method of triggering asensor implanted within a living animal to measure a concentration of ananalyte in a medium within the living animal. The method may includecoupling an inductive element of an external reader and an inductiveelement of the sensor within an electrodynamic field. The method mayinclude generating field strength data indicative of the strength of thecoupling of the inductive element of the external reader and theinductive element of the sensor. The method may include determining,based on the field strength data, whether the strength of the couplingof the inductive element of the external reader and the inductiveelement of the sensor is sufficient for the sensor to perform an analyteconcentration measurement and convey the results thereof to the externalreader. The method may include, if the strength of the coupling of theinductive element of the external reader and the inductive element ofthe sensor is determined to be sufficient, triggering an analyteconcentration measurement by the sensor and conveyance the resultsthereof to the external reader.

In some embodiments, the external reader may generate the field strengthdata by producing, using circuitry of the external reader, a couplingvalue proportional to the strength of the coupling of the inductiveelement of the external reader and the inductive element of the sensor.

In some embodiments, the method may include producing, using circuitryof the sensor, a coupling value proportional to the strength of thecoupling of the inductive element of the external reader and theinductive element of the sensor. The method may include modulating,using circuitry of the sensor, the electrodynamic field based on thecoupling value proportional to the strength of the coupling of theinductive element of the external reader and the inductive element ofthe sensor. The external reader may generate the field strength data bydecoding, using circuitry of the external reader, the modulation of theelectrodynamic field. The method may include converting, using circuitryof the sensor, the coupling value into a digital coupling value. Themethod may include, modulating, using circuitry of the sensor, theelectrodynamic field based on the digital coupling value. The externalreader may generate the field strength data by decoding, using circuitryof the external reader, the modulation of the electrodynamic field.

In some embodiments, the field strength data may be a value proportionalto the strength of the coupling of the inductive element of the externalreader and the inductive element of the sensor. Determining whether thestrength of the coupling is sufficient may include comparing the fieldstrength data to a field strength sufficiency threshold. The strength ofthe coupling may be determined to be sufficient if the field strengthdata exceeds a field strength sufficiency threshold.

In some embodiments, the coupling may include moving the sensor and theexternal reader relative to each other such that the inductive elementof the external reader and the inductive element of the sensor arecoupled within the electrodynamic field.

In another aspect, the present invention provides a method of triggeringa sensor implanted within a living animal to measure a concentration ofan analyte in a medium within the living animal. The method may includegenerating, using an external reader, field strength data indicative ofthe strength of coupling of an inductive element of the external readerand an inductive element of the sensor within an electrodynamic field.The method may include determining, using the external reader, based onthe field strength data, whether the strength of the coupling of theinductive element of the external reader and the inductive element ofthe sensor is sufficient for the sensor to perform an analyteconcentration measurement and convey the results thereof to the externalreader. The method may include, if the strength of the coupling of theinductive element of the external reader and the inductive element ofthe sensor is determined to be insufficient, repeating the generatingand determining steps. The method may include, if the strength of thecoupling of the inductive element of the external reader and theinductive element of the sensor is determined to be sufficient,triggering, using the external reader, an analyte concentrationmeasurement by the sensor and conveyance the results thereof to theexternal reader, wherein the triggering comprises conveying, usingcircuitry of the external reader, an analyte measurement command to thesensor. The method may include decoding, using circuitry of the externalreader, analyte measurement information conveyed from the sensor.

In yet another aspect, the present invention provides a method oftriggering a sensor implanted within a living animal to measure aconcentration of an analyte in a medium within the living animal. Themethod may include producing, using circuitry of the sensor, a couplingvalue proportional to the strength of the coupling of the inductiveelement of an external reader and an inductive element of the sensorwithin an electrodynamic field. The method may include converting, usingcircuitry of the sensor, the coupling value into a digital couplingvalue. The method may include conveying, using circuitry of the sensor,the digital coupling value to the external reader. The method mayinclude decoding, using the circuitry of the sensor, an analytemeasurement command conveyed from the external reader. The method mayinclude executing, using the sensor, the analyte measurement command.The execution of the analyte measurement command may include generating,using the sensor, analyte measurement information indicative of theconcentration of the analyte in the medium within the living animal. Theexecution of the analyte measurement command may include conveying,using the inductive element of the implanted sensor, the analytemeasurement information.

In still another aspect, the present invention provides a sensor forimplantation within a living animal and measurement of a concentrationof an analyte in a medium within the living animal. The sensor mayinclude an inductive element configured to couple with an inductiveelement of an external reader within an electrodynamic field. The sensormay include an input/output circuit configured to produce a couplingvalue proportional to the strength of the coupling of the inductiveelement of the external reader and the inductive element of the sensorwithin the electrodynamic field. The input/output circuit may beconfigured to convey a digital coupling value to the external reader.The input/output circuit may be configured to decode an analytemeasurement command conveyed from the external reader. The input/outputcircuit may be configured to convey analyte measurement informationindicative of the concentration of the analyte in the medium within theliving animal. The sensor may include circuitry to convert the couplingvalue into a digital coupling value. The sensor may include ameasurement controller configured to: (i) control the input/outputcircuit to convey the digital coupling value; (ii) in accordance withthe analyte measurement command, generate the analyte measurementinformation indicative of the concentration of the analyte in the mediumwithin the living animal; and (iii) control the input/output circuit toconvey the analyte measurement information.

In another aspect, the present invention provides an external reader fortriggering a sensor implanted within a living animal to measure aconcentration of an analyte in a medium within the living animal. Theexternal reader may include an inductive element configured to couplewith an inductive element of an external reader within electrodynamicfield. The external reader may include circuitry configured to: (i)generate field strength data indicative of the strength of coupling ofan inductive element of the external reader and an inductive element ofthe sensor within an electrodynamic field; (ii) determine based on thefield strength data, whether the strength of the coupling of theinductive element of the external reader and the inductive element ofthe sensor is sufficient for the sensor to perform an analyteconcentration measurement and convey the results thereof to the externalreader; (iii) if the strength of the coupling of the inductive elementof the external reader and the inductive element of the sensor isdetermined to be insufficient, repeat the generating and determiningsteps; (iv) if the strength of the coupling of the inductive element ofthe external reader and the inductive element of the sensor isdetermined to be sufficient, trigger an analyte concentrationmeasurement by the sensor and conveyance the results thereof to theexternal reader, wherein the triggering comprises conveying an analytemeasurement command to the sensor; and (v) decode analyte measurementinformation conveyed from the sensor.

In another aspect, the present invention provides a method of triggeringa sensor implanted within a living animal to measure a concentration ofan analyte in a medium within the living animal. The method may includeproducing, using circuitry of the sensor, a coupling value proportionalto the strength of the coupling of the inductive element of an externalreader and an inductive element of the sensor within an electrodynamicfield. The method may include determining, using the sensor, based onthe coupling value, whether the strength of the coupling of theinductive element of the external reader and the inductive element ofthe sensor is sufficient for the sensor to perform an analyteconcentration measurement and convey the results thereof to the externalreader. The method may include, if the strength of the coupling of theinductive element of the external reader and the inductive element ofthe sensor is determined to be sufficient, executing, using the sensor,the analyte measurement command. The execution of the analytemeasurement command may include: generating, using the sensor, analytemeasurement information indicative of the concentration of the analytein the medium within the living animal; and conveying, using theinductive element of the implanted sensor, the analyte measurementinformation.

In another aspect, the present invention provides an external reader forobtaining an analyte measurement from an implanted sensor. The readermay include a housing, reader components, and a communication member.The reader components may be configured to wirelessly communicate withthe implanted sensor and obtain an analyte measurement from theimplanted sensor. The reader components may comprise a coil configuredto inductively couple with the implanted sensor. The communicationmember may be configured to communicate the analyte measurement to anelectronic device.

In another aspect, the present invention provides an external reader forobtaining analyte measurements from an implanted sensor and configuredto encase a smartphone including a communication port. The reader mayinclude a first casing including a first coupling member, a secondcasing including a second coupling member configured to couple with thefirst coupling member, a communication member configured to couple withthe communication port of the smartphone, and reader components. Thereader components may be configured to wirelessly communicate with theimplanted sensor and obtain an analyte measurement from the implantedsensor. The reader components comprise a coil configured to inductivelycouple with the implanted sensor.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view of a sensor system, which includes animplantable sensor and a sensor reader, embodying aspects of the presentinvention.

FIGS. 2A-2C illustrate example configurations of the inductive elementof the external sensor reader in accordance with embodiments of thepresent invention.

FIG. 3 illustrates a sensor in alignment with an electromagnetic fieldemitted by the inductive element of a transceiver in accordance with anembodiment of the present invention.

FIGS. 4-7 illustrate an external sensor reader that includes asmartphone and a smartphone case in accordance with an embodiment of thepresent invention. FIG. 4 illustrates a perspective view of an explodedsensor reader in accordance with an embodiment of the present invention.

FIGS. 5A and 5B illustrate perspective and side views, respectively, ofthe sensor reader with the smartphone case encasing the smartphone inaccordance with an embodiment of the present invention.

FIG. 6 illustrates a perspective view of the smartphone case of thesensor reader without the smartphone in accordance with an embodiment ofthe present invention.

FIG. 7 illustrates a perspective view of the sensor reader with thesmartphone case encasing the smartphone and the bottom casing shown astransparent in accordance with an embodiment of the present invention.

FIG. 8 illustrates an external sensor reader that includes a smartphoneand an adapter in accordance with an embodiment of the presentinvention.

FIG. 9 illustrates an external sensor reader that is a dedicated readerdevice in accordance with an embodiment of the present invention.

FIG. 10 illustrates an external sensor reader that is an adaptablereader device in accordance with an embodiment of the present invention.

FIG. 11A is a schematic, section view illustrating a sensor embodyingaspects of the present invention.

FIGS. 11B and 11C illustrate perspective views of a sensor embodyingaspects of the present invention.

FIG. 11D is block diagram illustrating the functional blocks of thecircuitry of a sensor according to an embodiment in which the circuitryis fabricated in the semiconductor substrate.

FIG. 12 illustrates an alternative embodiment of a sensor embodyingaspects of the present invention.

FIG. 13 is a block diagram illustrating functional blocks of thecircuitry of an external sensor reader according to an embodiment of thepresent invention.

FIGS. 14A-14C illustrate a user using an external sensor readeraccording to an embodiment of the present invention.

FIG. 15 illustrates an exemplary sensor reader control process that maybe performed by the sensor reader in accordance with an embodiment ofthe present invention.

FIG. 16 illustrates an exemplary sensor control process that may beperformed by the sensor in accordance with an embodiment of the presentinvention.

FIG. 17 illustrates a measurement command execution process that may beperformed by the sensor to execute a measurement command received by thesensor in accordance with an embodiment of the present invention.

FIG. 18 illustrates a measurement and conversion process that may beperformed in a step of the measurement command execution process, inaccordance with an embodiment of the present invention.

FIG. 19 illustrates a get result command execution process that may beperformed by the sensor to execute a get result command received by thesensor in accordance with an embodiment of the present invention.

FIG. 20 illustrates a get identification information command executionprocess that may be performed by the sensor to execute a getidentification information command received by the sensor in accordancewith an embodiment of the present invention.

FIGS. 21A and 21B illustrate the timing of an exemplary embodiment of ameasurement and conversion process in accordance with an embodiment ofthe present invention.

FIG. 22 illustrates an alternative sensor control process that may beperformed by the sensor in accordance with an embodiment of the presentinvention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 is a schematic view of a sensor system embodying aspects of thepresent invention. In one non-limiting embodiment, the system includes asensor 100 and an external sensor reader 101. In the embodiment shown inFIG. 1, the sensor 100 is implanted in a living animal (e.g., a livinghuman). The sensor 100 may be implanted, for example, in a livinganimal's arm, wrist, leg, abdomen, or other region of the living animalsuitable for sensor implantation. For example, as shown in FIG. 1, inone non-limiting embodiment, the sensor 100 may be implanted between theskin 109 and subcutaneous tissues 111. In some embodiments, the sensor100 may be an optical sensor. In some embodiments, the sensor 100 may bea chemical or biochemical sensor.

A sensor reader 101 may be an electronic device that communicates withthe sensor 100 to power the sensor 100 and/or obtain analyte (e.g.,glucose) readings from the sensor 100 on demand. In non-limitingembodiments, the reader 101 may be a handheld reader. In one embodiment,positioning (i.e., hovering or swiping/waiving/passing) the reader 101within range over the sensor implant site (i.e., within proximity of thesensor 100) will cause the reader 101 to automatically convey ameasurement command to the sensor 100 and receive a reading from thesensor 100. The reader 101 may subsequently be returned to a user'sstorage space, such as, for example, a user's purse or pocket. In othernon-limiting embodiments, the reader may be stationary, for example,with a simple loop (i.e., coil) through which a user thrusts their wristand a sensor 100 embedded therein. Thus, in such embodiments, thestationary reader could sit on a table or bathroom counter (or wherever)for occasional use by the user, and the user could, for example, wake upeach morning and move their wrist through a coil while brushing theirteeth.

In some embodiments, the sensor reader 101 may include a transceiver103, a processor 105 and/or a user interface 107. In one non-limitingembodiment, the user interface 107 may include a liquid crystal display(LCD), but, in other embodiments, different types of displays may beused. In some embodiments, the transceiver 103 may include an inductiveelement, such as, for example, a coil. The transceiver 103 may generatean electromagnetic wave or electrodynamic field (e.g., by using a coil)to induce a current in an inductive element (e.g., inductive element 114of FIGS. 11A-11C) of the sensor 100, which powers the sensor 100. Thetransceiver 103 may also convey data (e.g., commands) to the sensor 100.For example, in a non-limiting embodiment, the transceiver 103 mayconvey data by modulating the electromagnetic wave used to power thesensor 100 (e.g., by modulating the current flowing through a coil ofthe transceiver 103). The modulation in the electromagnetic wavegenerated by the reader 101 may be detected/extracted by the sensor 100(e.g., by data extractor 642 of FIG. 11D). Moreover, the transceiver 103may receive data (e.g., measurement information) from the sensor 100.For example, in a non-limiting embodiment, the transceiver 103 mayreceive data by detecting modulations in the electromagnetic wavegenerated by the sensor 100 (e.g., by clamp/modulator 646 of FIG. 11D),e.g., by detecting modulations in the current flowing through the coilof the transceiver 103.

The inductive element of the transceiver 103 and the inductive element(e.g., inductive element 114 of FIGS. 11A-11C) of the sensor 100 may bein any configuration that permits adequate field strength to be achievedwhen the two inductive elements are brought within adequate physicalproximity. The inductive element of the sensor 100 (i.e., the secondaryinductive element), which may comprise a coil (e.g., coil 220 of FIG.11D), may be contained within the sensor and may be a fixed element inalignment according to the implantation of the sensor 100. FIGS. 2A-2Cillustrate examples of the inductive element of transceiver 103 (i.e.,the primary inductive element), which may comprise a coil (i.e., theprimary coil). FIG. 2A illustrates an example of a cylindrical coil.FIG. 2B illustrates a square or rectangular coil. FIG. 2C illustrates aFIG. 8 or planar coil. The transceiver may include a coil in any ofthese configurations for alignment with the coil of the sensor 100.Alternatively, the transceiver 103 may have any coil with natural fieldalignment vectors sufficiently coaxial with the secondary coil such thatthe primary and secondary coils between the reader 101 and sensor 100,respectively, can achieve adequate field strength within some physicalproximity.

The primary coil configurations illustrated in FIGS. 2A-2C (or othersuitable primary coil configuration) may or may not have ferrite cores.FIG. 3 illustrates a non-limiting embodiment of a sensor 100 inalignment with an electromagnetic field emitted by the inductive element313 of transceiver 103. In the illustrated embodiment, the inductiveelement 313 is a FIG. 8 or planar coil having a substrate 315.

The sensor reader 101 may be capable of communicating with otherelectronic devices, like smartphones or computers. In some embodiments,the reader 101 may communicate with the sensor 100 in less than onesecond (e.g., in approximately 10 milliseconds), and a swiping motion ofthe sensor reader over the area where the sensor was inserted may,therefore, be enough to obtain a reading/measurement from the sensor100. In some embodiments, the sensor reader 101 may then communicatewith, for example, a computer, iPhone, or any other smartphone fordisplay purposes. The sensor reader 101 may have different embodimentsand different ways of communicating with other electronic devices. Inone embodiment, the sensor reader 101 may be a small container or box(or any convenient form factor) carried in a bag, purse, or pocket (seeFIG. 9). In another embodiment, the sensor reader 101 can be carried asa key fob or worn on a neck lanyard, or, as noted above, the sensorreader 101 might sit on a table or a bathroom counter to be operated andhave a loop antenna into which a user transiently inserts a body part(e.g., wrist) into which a sensor 100 has been implanted. In theseexamples, the reader 101 could communicate through Bluetooth or otherwireless radio standard to a smartphone or computer, or the sensorreader 101 could be physically connected to the other electronic devicethrough a pin or cable. In some embodiments, the sensor reader 101 maybe a smartphone case (see FIGS. 4A-7E). The case may contain the sameelectronics as the small container or box, and the case may either drawpower from the phone through a port connection or it can requireseparate charging. The case may also communicate with the smartphonethrough the same port connection. To obtain a glucose reading, the usermay simply swipe the encased smartphone over the sensor and the readingwould be displayed, for example, in the smartphone screen.

The sensor reader may communicate with and/or power the implantedsensor, for example, through inductive coupling as described in U.S.Pat. No. 7,553,280, which is incorporated by reference herein in itsentirety. In an embodiment of the present invention, the implantedsensor 100 is passive and the sensor reader 101 powers the sensor 100through inductive coupling. In one non-limiting embodiment, the internalsensor unit 100 may include a secondary coil forming part of a powersupply for the sensor unit, a load coupled to said secondary coil, and asensor circuit for modifying said load in accordance with sensormeasurement information obtained by the sensor circuit. The swipe reader101 may include a primary coil that is mutually inductively coupled tothe secondary coil upon the primary coil coming into a predeterminedproximity distance from said secondary coil, an oscillator for drivingsaid primary coil to induce a charging current in said secondary coil,and a detector for detecting variations in a load on the primary coilinduced by changes to the load in the internal sensor unit and forproviding information signals corresponding to the load changes.

In some non-limiting embodiments, the inductive element of thetransceiver 103 of the reader 101 may be a coil contained within anadaptable reader device, such as a smartphone or tablet (see FIG. 10),or the inductive element of the transceiver 103 may be a part of anadapter or an add-on to such a device (see FIG. 8), such as a cover fora smart phone type handheld (see FIGS. 4A-7E), or a piggyback designconnected by wireless protocol or cable, or may be included in thedesign and construction of a dedicated reader device (see FIG. 9) suchas a smart phone, dedicated handheld reader, wand, or adapter that willenable triggered readings of an implanted sensor during transientproximal motion within range.

In some embodiments, the processor 105 may output to the transceiver 103the data to be conveyed to the sensor 100 and may receive from thetransceiver 103 the data received from the sensor 100. In oneembodiment, the processor 105 may serialize and encode the data to beconveyed to the sensor 100 before outputting it to the transceiver 103for transmission. Similarly, the processor 105 may decode and/orserialize the data received from the sensor 100. In some embodiments,the data received from the sensor 100 may be measurement information,and the processor 105 may process the measurement information todetermine a concentration of an analyte. However, in other embodiments,the sensor 100 may process the measurement information to determine aconcentration of an analyte, and the data received from the sensor 100may be the determined concentration of the analyte. In some embodiments,the processor 105 may cause the user interface 107 to display a valuerepresenting the concentration of the analyte so that a user (e.g., thepatient, a doctor and/or others) can read the value. Also, in someembodiments, the processor 105 may receive from the user interface 107user input (e.g., a user request for a sensor reading, such as theconcentration of an analyte). Furthermore, in some embodiments, thesensor reader 101 may include one or more input/output ports that enabletransmission of data (e.g., traceability information and/or measurementinformation) and receipt of data (e.g., sensor commands and/or setupparameters) between the sensor reader 101 and another device (e.g., acomputer and/or smartphone).

FIGS. 4-7 illustrate a non-limiting embodiment of an external sensorreader 101 a that includes a smartphone 206 and an adapter in the formof a smartphone case. FIG. 4 illustrates a perspective view of anexploded sensor reader 101 a. FIGS. 5A and 5B illustrate perspective andside views, respectively, of the sensor reader 101 a with the smartphonecase encasing the smartphone 206. FIG. 6 illustrates a perspective viewof the smartphone case of the sensor reader 101 a without the smartphone206. FIG. 7 illustrates a perspective view of the sensor reader 101 awith the smartphone case encasing the smartphone 206 and the bottomcasing 202 shown as transparent.

The smartphone 206 may act as the user interface (see user interface 107of FIG. 1) of sensor reader 101 a. In addition, the smartphone 206 mayprovide none, some, or all of the processing functionality (seeprocessor 105 of FIG. 1) of the sensor reader 101 a. The smartphone casemay have reading components 225 that may act as the transceiver (seetransceiver 103 of FIG. 1) and may provide none, some, or all of theprocessing functionality (see processor 105 of FIG. 1) of the sensorreader 101 a.

The sensor reader 101 a may be configured to read and/or power aninternal sensor (e.g., sensor 100) when swiped or moved within a maximumdistance, e.g., one inch, of the internal sensor. The smartphone casemay include a bottom casing 202 and a top casing 204. The bottom casing202 and top casing 204 may be configured to encase the smartphone 206.In some embodiments, the smartphone 206 may include a port 208, and thebottom casing 202 may include a coupling member or pin 210 configured tobe inserted into and couple with the port 208 of the smartphone 206. Thesmartphone casing may be configured such that, when the pin 210 ofbottom casing 202 is coupled with the port 208 of the smartphone 206,the smartphone casing and the smartphone 206 can communicate with eachother. Additionally or alternatively, the smartphone casing may beconfigured such that, when the pin 210 of bottom casing 202 is coupledwith the port 208 of the smartphone 206, the smartphone 206 suppliespower to the sensor reader 101 a via the port connection, i.e., via thepin 210 being inserted into the port 208.

In some embodiments of the present invention, the smartphone 206 mayinclude a display 212. The display 212 can be configured to display theanalyte (e.g., glucose) measurements obtained from sensor 100. In someembodiments of the present invention, the top casing 204 may includeopenings 214 configured to allow the interactive and functional featuresof the smartphone 206 (e.g., volume control, power button, and/or audioports) to remain unobstructed when the smartphone casing encases thesmartphone 206. In some non-limiting embodiments, the bottom casing 202may include a port 216 configured to receive a pin. The bottom casingport 216 can be used to communicate information to another electronicdevice (e.g., a computer or different smartphone). In some embodiments,the port 216 may also be used to allow electronic devices to communicatewith the smartphone 206.

In some embodiments of the present invention, the bottom casing 202 mayinclude a coupling member 218, and the top casing 204 may include acoupling member 221 (see FIG. 6). The coupling members 218 and 221 maybe configured to couple such that the bottom casing 202 and the topcasing 204 encase the smartphone 206. In a non-limiting embodiment ofthe present invention, the bottom casing coupling member 218 may be aprotrusion, and the top casing coupling member 221 may be an openingconfigured to receive the bottom casing coupling member 218. Thecoupling members 218 and 221 may be configured to allow a user to coupleand decouple the casing from the smartphone 206 (i.e., the couplingmembers 218 and 221 do not permanently couple).

In some embodiments, the bottom casing 202 may include the circuitry andcomponents for reading the sensor 100. The bottom casing 202 may includea housing 223 and reading components 225, as illustrated in FIG. 7. Thereading components may include an inductive element (e.g., a coil), anoscillator, and/or a detector. Such reading components are described infurther detail in U.S. Pat. No. 7,553,280, which is incorporated byreference herein in its entirety. In a non-limiting embodiment of thepresent invention, the bottom casing 202 may additionally include apower source, such as a battery.

FIG. 8 illustrates a non-limiting embodiment of an external sensorreader 101 b that includes a smartphone 304 and an adapter 302. Unlikethe adapter of sensor reader 101 a, the adapter 302 of sensor reader 101b is not in the form of a smartphone case. The adapter 302 of sensorreader 101 b may be configured to couple to a smartphone 304. Theadapter 302 may include a pin, as described above (see pin 210 of FIGS.4A, 4E, 6A, and 6B), configured to couple with a port of the smartphone304. The adapter 302 may include reading components (see readingcomponents 225 of FIGS. 7A-7E) configured to read and/or power aninternal sensor. The smartphone 304 can include a display 306, which candisplay the analyte values obtained from the sensor.

FIG. 9 illustrates a non-limiting embodiment of an external sensorreader 101 c that is a dedicated reader device, such as a smart phone,dedicated handheld reader, wand, or adapter, that will enable triggeredreadings of an implanted sensor 100 during transient proximal motionwithin range. The dedicated reader device may act as the user interface(see user interface 107 of FIG. 1) and transceiver (see transceiver 103of FIG. 1) of sensor reader 101 c and may provide all of the processingfunctionality (see processor 105 of FIG. 1) of the sensor reader 101 c.Furthermore, in a non-limiting embodiment, the sensor reader 101 c mayinclude one or more input/output ports that enable transmission (e.g.,via wireless radio technology, such as Bluetooth low energy) of andreceipt of data (e.g., sensor commands and/or setup parameters) betweenthe sensor reader 101 and another device (e.g., a computer and/orsmartphone).

FIG. 10 illustrates a non-limiting embodiment of an external sensorreader 101 d that is an adaptable reader device, such as a smartphone ortablet, having an inductive element (e.g., a coil) contained within theadaptable reader device. The adaptable reader device may act as the userinterface (see user interface 107 of FIG. 1) and transceiver (seetransceiver 103 of FIG. 1) of sensor reader 101 d and may provide all ofthe processing functionality (see processor 105 of FIG. 1) of the sensorreader 101 d.

FIG. 11A is a schematic, section view of a sensor 100 a, which is anembodiment of the sensor embodying aspects of the present invention. Insome embodiments, the sensor 100 may be an optical sensor. In onenon-limiting embodiment, sensor 100 includes a sensor housing 102. Inexemplary embodiments, sensor housing 102 may be formed from a suitable,optically transmissive polymer material, such as, for example, acrylicpolymers (e.g., polymethylmethacrylate (PMMA)).

In the embodiment illustrated in FIG. 11A, the sensor 100 includesindicator molecules 104. Indicator molecules 104 may be fluorescentindicator molecules or absorption indicator molecules. In somenon-limiting embodiments, sensor 100 may include a matrix layer 106coated on at least part of the exterior surface of the sensor housing102, with the indicator molecules 104 distributed throughout the matrixlayer 106. The matrix layer 106 may cover the entire surface of sensorhousing 102 or only one or more portions of the surface of housing 102.Similarly, the indicator molecules 104 may be distributed throughout theentire matrix layer 106 or only throughout one or more portions of thematrix layer 106. Furthermore, as an alternative to coating the matrixlayer 106 on the outer surface of sensor housing 102, the matrix layer106 may be disposed on the outer surface of the sensor housing 102 inother ways, such as by deposition or adhesion.

In the embodiment illustrated in FIG. 11A, the sensor 100 includes alight source 108, which may be, for example, a light emitting diode(LED) or other light source, that emits radiation, including radiationover a range of wavelengths that interact with the indicator molecules104.

In the embodiment illustrated in FIG. 11A, sensor 100 also includes oneor more photodetectors 110 (e.g., photodiodes, phototransistors,photoresistors or other photosensitive elements) which, in the case of afluorescence-based sensor, is sensitive to fluorescent light emitted bythe indicator molecules 104 such that a signal is generated by thephotodetector 110 in response thereto that is indicative of the level offluorescence of the indicator molecules and, thus, the amount of analyteof interest (e.g., glucose).

As illustrated in FIG. 11A, some embodiments of sensor 100 include oneor more optical filters 112, such as high pass or band pass filters,that may cover a photosensitive side of the one or more photodetectors110.

As shown in FIG. 11A, in some embodiments, sensor 100 may be whollyself-contained. In other words, the sensor may be constructed in such away that no electrical leads extend into or out of the sensor housing102 to supply power to the sensor (e.g., for driving the light source108) or to convey signals from the sensor 100. Instead, in oneembodiment, sensor 100 may be powered by an external power source (e.g.,external sensor reader 101). For example, the external power source maygenerate a magnetic field to induce a current in an inductive element114 (e.g., a coil or other inductive element). Additionally, the sensor100 may use the inductive element 114 to communicate information to anexternal data reader (not shown). In some embodiments, the externalpower source and data reader may be the same device.

In some embodiments, sensor 100 includes a semiconductor substrate 116.In the embodiment illustrated in FIG. 11A, circuitry is fabricated inthe semiconductor substrate 116. The circuitry may include analog and/ordigital circuitry. Also, although in some preferred embodiments thecircuitry is fabricated in the semiconductor substrate 116, inalternative embodiments, a portion or all of the circuitry may bemounted or otherwise attached to the semiconductor substrate 116. Inother words, in alternative embodiments, a portion or all of thecircuitry may include discrete circuit elements, an integrated circuit(e.g., an application specific integrated circuit (ASIC)) and/or otherelectronic components discrete and may be secured to the semiconductorsubstrate 116, which may provide communication paths between the varioussecured components.

In some embodiments, the one or more photodetectors 110 may be mountedon the semiconductor substrate 116, but, in some preferred embodiments,the one or more photodetectors 110 may be fabricated in thesemiconductor substrate 116. In some embodiments, the light source 108may be mounted on the semiconductor substrate 116. For example, in anon-limiting embodiment, the light source 108 may be flip-chip mountedon the semiconductor substrate 116. However, in some embodiments, thelight source 108 may be fabricated in the semiconductor substrate 116.

As shown in the embodiment illustrated in FIG. 11A, in some embodiments,the sensor 100 may include one or more capacitors 118. The one or morecapacitors 118 may be, for example, one or more tuning capacitors and/orone or more regulation capacitors. The one or more capacitors 118 may betoo large for fabrication in the semiconductor substrate 116 to bepractical. Further, the one or more capacitors 118 may be in addition toone or more capacitors fabricated in the semiconductor substrate 116.

In some embodiments, the sensor 100 may include a reflector (i.e.,mirror) 119. As shown in FIG. 11A, reflector 119 may be attached to thesemiconductor substrate 116 at an end thereof. In a non-limitingembodiment, reflector 119 may be attached to the semiconductor substrate116 so that a face portion 121 of reflector 119 is generallyperpendicular to a top side of the semiconductor substrate 116 (i.e.,the side of semiconductor substrate 116 on or in which the light source108 and one or more photodetectors 110 are mounted or fabricated) andfaces the light source 108. The face 121 of the reflector 119 mayreflect radiation emitted by light source 108. In other words, thereflector 119 may block radiation emitted by light source 108 fromentering the axial end of the sensor 100.

According to one aspect of the invention, an application for which thesensor 100 was developed—although by no means the only application forwhich it is suitable—is measuring various biological analytes in theliving body of an animal (including a human). For example, sensor 110may be used to measure glucose, oxygen, toxins, pharmaceuticals or otherdrugs, hormones, and other metabolic analytes in, for example, the humanbody. The specific composition of the matrix layer 104 and the indicatormolecules 106 may vary depending on the particular analyte the sensor isto be used to detect and/or where the sensor is to be used to detect theanalyte (i.e., in the blood or in subcutaneous tissues). Preferably,however, matrix layer 104, if present, should facilitate exposure of theindicator molecules to the analyte. Also, it is preferred that theoptical characteristics of the indicator molecules (e.g., the level offluorescence of fluorescent indicator molecules) be a function of theconcentration of the specific analyte to which the indicator moleculesare exposed.

FIGS. 11B and 11C illustrate perspective views of the sensor 100. InFIGS. 11B and 11C, the reflector 119, which may be included in someembodiments of the sensor 100, is not illustrated. In the embodimentillustrated in FIGS. 11B and 11C, the inductive element 114 comprises acoil 220. In one embodiment, coil 220 may be a copper coil but otherconductive materials, such as, for example, screen printed gold, mayalternatively be used. In some embodiments, the coil 220 is formedaround a ferrite core 222. Although core 222 is ferrite in someembodiments, in other embodiments, other core materials mayalternatively be used. In some embodiments, coil 220 is not formedaround a core. Although coil 220 is illustrated as a cylindrical coil inFIGS. 11B and 11C, in other embodiments, coil 220 may be a differenttype of coil, such as, for example, a flat coil.

In some embodiments, coil 220 is formed on ferrite core 222 by printingthe coil 220 around the ferrite core 222 such that the major axis of thecoil 220 (magnetically) is parallel to the longitudinal axis of theferrite core 222. A non-limiting example of a coil printed on a ferritecore is described in U.S. Pat. No. 7,800,078, which is incorporatedherein in its entirety. In an alternative embodiment, coil 220 may be awire-wound coil. However, embodiments in which coil 220 is a printedcoil as opposed to a wire-wound coil are preferred because eachwire-wound coil is slightly different in characteristics due tomanufacturing tolerances, and it may be necessary to individually tuneeach sensor that uses a wire-wound coil to properly match the frequencyof operation with the associated antenna. Printed coils, by contrast,may be manufactured using automated techniques that provide a highdegree of reproducibility and homogeneity in physical characteristics,as well as reliability, which is important for implant applications, andincreases cost-effectiveness in manufacturing.

In some embodiments, a dielectric layer may be printed on top of thecoil 220. The dielectric layer may be, in a non-limiting embodiment, aglass based insulator that is screen printed and fired onto the coil220. In an exemplary embodiment, the one or more capacitors 118 and thesemiconductor substrate 116 may be mounted on vias through thedielectric.

In the embodiment illustrated in FIGS. 11B and 11C, the one or morephotodetectors 110 include a first photodetector 224 and a secondphotodetector 226. First and second photodetectors 224 and 226 may bemounted on or fabricated in the semiconductor substrate 116. In theembodiment illustrated in FIGS. 11B and 11C, sensor 100 may include oneor more optical filters 112 even though they are not shown.

FIG. 11D is block diagram illustrating the functional blocks of thecircuitry of sensor 100 according to a non-limiting embodiment in whichthe circuitry is fabricated in the semiconductor substrate 116. As shownin the embodiment of FIG. 11D, in some embodiments, an input/output(I/O) frontend block 536 may be connected to the external inductiveelement 114, which may be in the form of a coil 220, through coilcontacts 428 a and 428 b. The I/O frontend block 536 may include arectifier 640, a data extractor 642, a clock extractor 644,clamp/modulator 646 and/or frequency divider 648. Data extractor 642,clock extractor 644 and clamp/modulator 646 may each be connected toexternal coil 220 through coil contacts 428 a and 428 b. The rectifier640 may convert an alternating current produced by coil 220 to a directcurrent that may be used to power the sensor 100. For instance, thedirect current may be used to produce one or more voltages, such as, forexample, voltage VDD_A, which may be used to power the one or morephotodetectors 110. In one non-limiting embodiment, the rectifier 640may be a Schottky diode; however, other types of rectifiers may be usedin other embodiments. The data extractor 642 may extract data from thealternating current produced by coil 220. The clock extractor 644 mayextract a signal having a frequency (e.g., 13.56 MHz) from thealternating current produced by coil 220. The frequency divider 648 maydivide the frequency of the signal output by the clock extractor 644.For example, in a non-limiting embodiment, the frequency divider 648 maybe a 4:1 frequency divider that receives a signal having a frequency(e.g., 13.56 MHz) as an input and outputs a signal having a frequency(e.g., 3.39 MHz) equal to one fourth the frequency of the input signal.The outputs of rectifier 640 may be connected outputs of rectifier 640may be connected to one or more external capacitors 118 (e.g., one ormore regulation capacitors) through contacts 428 h and 428 i.

In some embodiments, an I/O controller 538 may include adecoder/serializer 650, command decoder/data encoder 652, data andcontrol bus 654, data serializer 656 and/or encoder 658. Thedecoder/serializer 650 may decode and serialize the data extracted bythe data extractor 642 from the alternating current produced by coil220. The command decoder/data encoder 652 may receive the data decodedand serialized by the decoder/serializer 650 and may decode commandstherefrom. The data and control bus 654 may receive commands decoded bythe command decoder/data encoder 652 and transfer the decoded commandsto the measurement controller 532. The data and control bus 654 may alsoreceive data, such as measurement information, from the measurementcontroller 532 and may transfer the received data to the commanddecoder/data encoder 652. The command decoder/data encoder 652 mayencode the data received from the data and control bus 654. The dataserializer 656 may receive encoded data from the command decoder/dataencoder 652 and may serialize the received encoded data. The encoder 658may receive serialized data from the data serializer 656 and may encodethe serialized data. In a non-limiting embodiment, the encoder 658 maybe a Manchester encoder that applies Manchester encoding (i.e., phaseencoding) to the serialized data. However, in other embodiments, othertypes of encoders may alternatively be used for the encoder 658, suchas, for example, an encoder that applies 8B/10B encoding to theserialized data.

The clamp/modulator 646 of the I/O frontend block 536 may receive thedata encoded by the encoder 658 and may modulate the current flowingthrough the inductive element 114 (e.g., coil 220) as a function of theencoded data. In this way, the encoded data may be conveyed wirelesslyby the inductive element 114 as a modulated electromagnetic wave. Theconveyed data may be detected by an external reading device by, forexample, measuring the current induced by the modulated electromagneticwave in a coil of the external reading device. Furthermore, bymodulating the current flowing through the coil 220 as a function of theencoded data, the encoded data may be conveyed wirelessly by the coil220 as a modulated electromagnetic wave even while the coil 220 is beingused to produce operating power for the sensor 100. See, for example,U.S. Pat. Nos. 6,330,464 and 8,073,548, which are incorporated herein byreference in their entireties and which describe a coil used to provideoperative power to an optical sensor and to wirelessly convey data fromthe optical sensor. In some embodiments, the encoded data is conveyed bythe sensor 100 using the clamp/modulator 646 at times when data (e.g.,commands) are not being received by the sensor 100 and extracted by thedata extractor 642. For example, in one non-limiting embodiment, allcommands may be initiated by an external sensor reader (e.g., sensor1500 of FIG. 15) and then responded to by the sensor 100 (e.g., after oras part of executing the command). In some embodiments, thecommunications received by the inductive element 114 and/or thecommunications conveyed by the inductive element 114 may be radiofrequency (RF) communications. Although, in the illustrated embodiments,the sensor 100 includes a single coil 220, alternative embodiments ofthe sensor 100 may include two or more coils (e.g., one coil for datatransmission and one coil for power and data reception).

In an embodiment, the I/O controller 538 may also include a nonvolatilestorage medium 660. In a non-limiting embodiment, the nonvolatilestorage medium 660 may be an electrically erasable programmable readonly memory (EEPROM). However, in other embodiments, other types ofnonvolatile storage media, such as flash memory, may be used. Thenonvolatile storage medium 660 may receive write data (i.e., data to bewritten to the nonvolatile storage medium 660) from the data and controlbus 654 and may supply read data (i.e., data read from the nonvolatilestorage medium 660) to the data and control bus 654. In someembodiments, the nonvolatile storage medium 660 may have an integratedcharge pump and/or may be connected to an external charge pump. In someembodiments, the nonvolatile storage medium 660 may store identificationinformation (i.e., traceability or tracking information), measurementinformation and/or setup parameters (i.e., calibration information). Inone embodiment, the identification information may uniquely identify thesensor 100. The unique identification information may, for example,enable full traceability of the sensor 100 through its production andsubsequent use. In one embodiment, the nonvolatile storage medium 660may store calibration information for each of the various sensormeasurements.

In some embodiments, the analog interface 534 may include a light sourcedriver 662, analog to digital converter (ADC) 664, a signal multiplexer(MUX) 666 and/or comparator 668. In a non-limiting embodiment, thecomparator 668 may be a transimpedance amplifier, in other embodiments,different comparators may be used. The analog interface 534 may alsoinclude light source 108, one or more photodetectors 110 (e.g., firstand second photodetectors 224 and 226) and/or a temperature transducer670. In a non-limiting, exemplary embodiment, the temperature transducer670 may be a band-gap based temperature transducer. However, inalternative embodiments, different types of temperature transducers maybe used, such as, for example, thermistors or resistance temperaturedetectors. Furthermore, like the light source 108 and one or morephotodetectors 110, in one or more alternative embodiments, thetemperature transducer 670 may be mounted on semiconductor substrate 116instead of being fabricated in semiconductor substrate 116.

The light source driver 662 may receive a signal from the measurementcontroller 532 indicating the light source current at which the lightsource 108 is to be driven, and the light source driver 662 may drivethe light source 108 accordingly. The light source 108 may emitradiation from an emission point in accordance with a drive signal fromthe light source driver 662. The radiation may excite indicatormolecules 104 distributed throughout a matrix layer 106 coated on atleast part of the exterior surface of the sensor housing 102. The one ormore photodetectors 110 (e.g., first and second photodetectors 224 and226) may each output an analog light measurement signal indicative ofthe amount of light received by the photodetector. For instance, in theembodiment illustrated in FIG. 11D, the first photodetector 224 mayoutput a first analog light measurement signal indicative of the amountof light received by the first photodetector 224, and the secondphotodetector 226 may output a first analog light measurement signalindicative of the amount of light received by the second photodetector226. The comparator 668 may receive the first and second analog lightmeasurement signals from the first and second photodetectors 224 and226, respectively, and output an analog light difference measurementsignal indicative of the difference between the first and second analoglight measurement signals. The temperature transducer 670 may output ananalog temperature measurement signal indicative of the temperature ofthe sensor 100. The signal MUX 666 may select one of the analogtemperature measurement signal, the first analog light measurementsignal, the second analog light measurement signal and the analog lightdifference measurement signal and may output the selected signal to theADC 664. The ADC 664 may convert the selected analog signal receivedfrom the signal MUX 666 to a digital signal and supply the digitalsignal to the measurement controller 532. In this way, the ADC 664 mayconvert the analog temperature measurement signal, the first analoglight measurement signal, the second analog light measurement signal andthe analog light difference measurement signal to a digital temperaturemeasurement signal, a first digital light measurement signal, a seconddigital light measurement signal and a digital light differencemeasurement signal, respectively, and may supply the digital signals,one at a time, to the measurement controller 532.

In some embodiments, the circuitry of sensor 100 fabricated in thesemiconductor substrate 116 may additionally include a clock generator671. The clock generator 671 may receive, as an input, the output of thefrequency divider 648 and generate a clock signal CLK. The clock signalCLK may be used by one or more components of one or more of the I/Ofronted block 536, I/O controller 538, measurement controller 532 andanalog interface 534.

In a non-limiting embodiment, data (e.g., decoded commands from thecommand decoder/data encoder 652 and/or read data from the nonvolatilestorage medium 660) may be transferred from the data and control bus 654of the I/O controller 538 to the measurement controller 532 via transferregisters and/or data (e.g., write data and/or measurement information)may be transferred from the measurement controller 532 to the data andcontrol bus 654 of the I/O controller 538 via the transfer registers.

In some embodiments, the circuitry of sensor 100 may include a fieldstrength measurement circuit. In embodiments, the field strengthmeasurement circuit may be part of the I/O front end block 536, I/Ocontroller 538, or the measurement controller 532 or may be a separatefunctional component. The field strength measurement circuit may measurethe received (i.e., coupled) power (e.g., in mWatts). The field strengthmeasurement circuit of the sensor 100 may produce a coupling valueproportional to the strength of coupling between the inductive element114 of the sensor 100 and the inductive element of the external reader101. For example, in non-limiting embodiments, the coupling value may bea current or frequency proportional to the strength of coupling. In someembodiments, the field strength measurement circuit may additionallydetermine whether the strength of coupling/received power is sufficientto perform an analyte concentration measurement and convey the resultsthereof to the external sensor reader 101. For example, in somenon-limiting embodiments, the field strength measurement circuit maydetect whether the received power is sufficient to produce a certainvoltage and/or current. In one non-limiting embodiment, the fieldstrength measurement circuit may detect whether the received powerproduces a voltage of at least approximately 3V and a current of atleast approximately 0.5 mA. However, other embodiments may detect thatthe received power produces at least a different voltage and/or at leasta different current. In one non-limiting embodiment, the field strengthmeasurement circuit may compare the coupling value field strengthsufficiency threshold.

In the illustrated embodiment, the clamp/modulator 646 of the I/Ocircuit 536 acts as the field strength measurement circuit by providinga value (e.g., I_(couple)) proportional to the field strength. The fieldstrength value I_(couple) may be provided as an input to the signal MUX666. When selected, the MUX 666 may output the field strength valueI_(couple) to the ADC 664. The ADC 664 may convert the field strengthvalue I_(couple) received from the signal MUX 666 to a digital fieldstrength value signal and supply the digital field strength signal tothe measurement controller 532. In this way, the field strengthmeasurement may be made available to the measurement controller 532 foruse in initiating an analyte measurement command trigger based ondynamic field alignment. However, in an alternative embodiment, thefield strength measurement circuit may instead be an analog oscillatorin the sensor 100 that sends a frequency corresponding to the voltagelevel on a rectifier 640 back to the reader 101.

FIG. 12 is a schematic, section view illustrating sensor 100 b, which isan alternative embodiment of the sensor 100. The sensor can be animplanted biosensor, such as the optical based biosensor described inU.S. Pat. No. 7,308,292, the disclosure of which is incorporated byreference herein in its entirety. The sensor 100 b may operate based onthe fluorescence of fluorescent indicator molecules 104. As shown,sensor 100 b may include a sensor housing 102 that may be formed from asuitable, optically transmissive polymer material. Sensor 100 b mayfurther include a matrix layer 106 coated on at least part of theexterior surface of the sensor housing 102, with fluorescent indicatormolecules 104 distributed throughout the layer 106 (layer 106 can coverall or part of the surface of housing 102). Sensor 100 b may include aradiation source 108, e.g., a light emitting diode (LED) or otherradiation source, that emits radiation, including radiation over a rangeof wavelengths which interact with the indicator molecules 104. Sensor100 b also includes a photodetector 110 (e.g., a photodiode,phototransistor, photoresistor or other photosensitive element) which,in the case of a fluorescence-based sensor, is sensitive to fluorescentlight emitted by the indicator molecules 104 such that a signal isgenerated by the photodetector 110 in response thereto that isindicative of the level of fluorescence of the indicator molecules. Twophotodetectors 110 are shown in FIG. 12 to illustrate that sensor 100 bmay have more than one photodetector.

The sensor 100 b may be powered by an external power source such as thesensor reader 101 of the present invention. For example, the externalpower source may generate a magnetic field to induce a current ininductive element 114 (e.g., a copper coil or other inductive element).Circuitry 166 may use inductive element 114 to communicate informationto the sensor reader 101. Circuitry 166 may include discrete circuitelements, an integrated circuit (e.g., an application specificintegrated circuit (ASIC), and/or other electronic components). Theexternal power source and data reader may be the same device.

In some embodiments, the circuitry 166 of sensor 100 b may include afield strength measurement circuit. The field strength measurementcircuit may measure the received (i.e., coupled) power (e.g., inmWatts). The field strength measurement circuit of circuitry 166 ofsensor 100 b may produce a coupling value proportional to the strengthof coupling between the inductive element 114 of the sensor 100 and theinductive element of the external reader 101. For example, innon-limiting embodiments, the coupling value may be a current orfrequency proportional to the strength of coupling. In some embodiments,the field strength measurement circuit may additionally determinewhether the strength of coupling is sufficient for the sensor to performan analyte concentration measurement and convey the results thereof tothe external sensor reader 101. For example, in some non-limitingembodiments, the circuitry 166 of sensor 100 b may detect whether thestrength of coupling is sufficient to produce a certain voltage and/orcurrent. In one non-limiting embodiment, the field strength measurementcircuit may compare the coupling value field strength sufficiencythreshold.

In some embodiments, the external sensor reader 101 may include a fieldstrength measurement circuit instead of (or in addition to) having afield strength measurement circuit in the sensor. FIG. 13 illustratesone non-limiting embodiment of an external sensor reader 101 having afield strength measurement circuit. As illustrated in FIG. 13, theexternal sensor 101 may include an inductive element (e.g., coil) 1302,power amplifier 1304, and a counter 1306, and the sensor 100 may includean inductive element (e.g., coil) 220, rectifier and power regulator640, clamp/modulator 646, rectifier capacitor C_(Rectifier), masterreset block 1308, power on reset block 1310, and initiate modulationblock 1312. The counter 1306 may act as a field strength measurementcircuit by counting/detecting the amount of time between when the reader101 begins supplying power (i.e., generates an electrodynamic field) andwhen the sensor 101 conveys a response communication (e.g., bymodulating the electrodynamic field), which is detected/decoded by theexternal reader 101. The longer it takes for the response communicationto be conveyed, the lower the field strength. In this way the counter1306 may produce a value proportional to the strength of coupling of theinductive element 1302 of the external reader 101 and the inductiveelement 220 of the sensor 100. In some embodiments, the value may be thecount or a current or voltage based on the count.

In the illustrated embodiment, once the reader 101 begins supplyingpower, a sensor 100 within the electrodynamic field may begin to buildcharge in the rectifier capacitor C_(Rectifier). Once a certain amount(i.e., the reset charge level) of charge is built up, the master resetblock 1308 may reset the sensor 101. Subsequently, the power on resetblock 1310 may start up the sensor 100, and the initiate modulate block1312 may cause a response communication to be conveyed to the reader 101via the clamp/modulator 646. The strength of the coupling of theinductive element 1302 of the external reader 101 and the inductiveelement 220 of the sensor 100 determines the amount of time it takes forthe rectifier capacitor C_(Rectifier) to charge up to the reset chargelevel, which determines the length of time it takes for the sensor 101to convey a response communication to the reader 101. After receivingthe response communication, the sensor reader 101 may stop supplyingpower.

In some embodiments, the reader 101 may use the value proportional tothe strength of coupling produced by the counter 1306 to determinewhether the strength of coupling is sufficient for the sensor 100 toperform an analyte measurement and to convey the result back to thereader 101.

FIGS. 14A-14C illustrate a user using a handheld external sensor reader101 according to an embodiment of the present invention. The user movesor swipes the sensor reader 101 within a distance, e.g., six inches, ofthe internal sensor 100, as shown in FIG. 14B. When the sensor reader101 is moved within the proximity of the sensor 100, and the strength ofthe electrodynamic field emitted by the inductive element of the sensorreader 101 and received by the inductive element of the sensor 100 issufficient for the sensor 100 to perform an analyte measurement, thesensor reader 101 may convey an analyte measurement command to thesensor 100, which executes the analyte measurement command and conveysthe analyte measurement information to the sensor reader 101. The sensorreader 101 may use the analyte measurement information to displayinformation representing the concentration of the analyte in a mediumwithin a living animal using the user interface 107 of the sensor reader101.

In one non-limiting embodiment, the measurement controller 532 of thesensor 100 may iteratively compare the value proportional to thecoupling strength (e.g., I_(couple)) as an indicator of relative fieldstrength, and, when the value meets or exceeds a threshold value suchthat the reader and sensor are sufficiently coupled within the field tosuccessfully exchange power and data, the measurement controller 532 mayissue a command to the reader to take an analyte reading/measurement,which is the motion transient trigger event. Following a successfulreading, the system may reset.

FIG. 15 illustrates an exemplary sensor reader control process 1500 thatmay be performed by the sensor reader 101 in accordance with anembodiment of the present invention. The sensor reader control process1500 may begin with a step 1502 of coupling the inductive element of theexternal reader 101 and the inductive element 114 of the sensor 100within an electrodynamic field. In one embodiment, the sensor reader 101may generate an electrodynamic field via an inductive element of thetransceiver 103 of the sensor reader 101 and may, thereby supply powerto a sensor 100 coupled within the electrodynamic field. In onenon-limiting embodiment, the coupling may comprise moving the sensor 100and the external reader 101 relative to each other such that theinductive element of the external reader 101 and the inductive element114 of the sensor 100 are coupled within the electrodynamic field.

In step 1504, the sensor reader 101 may generate field strength data. Insome embodiments, the reader 101 may generate the field strength data byproducing a coupling value proportional to the strength of the couplingof the inductive element of the external reader 101 and the inductiveelement 114 of the sensor 100. In one non-limiting embodiment, thecoupling value may be produced, for example, by the counter 1306 of thereader 101.

In other embodiments, the sensor 100 may produce the coupling valueproportional to the strength of the coupling of the inductive element ofthe external reader 101 and the inductive element 114 of the sensor 100and may convey the coupling value to the reader 101 (e.g., by modulatingthe electrodynamic field in accordance with the coupling value). Inthese embodiments, the reader 101 may generate the field strength databy decoding coupling value conveyed by the sensor 100. In someembodiments, the sensor 100 may convert (e.g., via ADC 664) the couplingvalue to a digital coupling value before conveying it to the reader 101.In some embodiments, the sensor 100 may additionally or alternativelyconvey an indication that the strength of the electrodynamic fieldreceived by the sensor 100 is either sufficient or insufficient for thesensor 100 to perform the analyte measurement and convey the analytemeasurement results to the reader 101.

In step 1506, the sensor reader 101 may determine whether the strengthof the electrodynamic field received by the sensor 100 is sufficient forthe sensor 100 to perform an analyte measurement based on the receivedfield strength data. In some non-limiting embodiments, step 1506 may beperformed by the processor 105 of the sensor reader 101. In somenon-limiting embodiments, the processor 105 of the sensor reader 101 maydetermine whether the strength of the electrodynamic field received bythe sensor 100 is sufficient by comparing the value proportional to thestrength of the electrodynamic field to an analyte measurement fieldstrength sufficiency threshold. In other embodiments, the processor 105of the sensor reader 101 may determine whether the strength of theelectrodynamic field received by the sensor 100 is sufficient based onan indication conveyed from the sensor 100 that the strength of theelectrodynamic field received by the implanted sensor 100 is eithersufficient or insufficient.

If the sensor reader 101 determines that the strength of theelectrodynamic field received by the sensor 100 is insufficient for thesensor 100 to perform an analyte concentration measurement and conveythe results thereof, the sensor reader control process 1500 may returnto step 1504 to receive generate additional field strength data. In somenon-limiting embodiments, if the sensor reader 101 determines that thestrength of the electrodynamic field received by the sensor 100 isinsufficient for the sensor 100 to perform an analyte measurement, thesensor reader 101 may notify the user that the strength of theelectrodynamic field received by the sensor 100 is insufficient. Forexample, the user may be notified by using the user interface 107 of thesensor reader 101. In some non-limiting embodiments, the user interface107 of the sensor reader 101 may display a signal strength indicatorwhenever the field strength data is available. In a non-limitingembodiment, the sensor reader 101 may display the value proportional tothe strength of the electrodynamic field, in an indication (e.g., apercentage, ratio, or bars) of the strength of the electrodynamic fieldreceived by the sensor 100 relative to the received strength that wouldbe sufficient for the sensor 100 to perform an analyte measurement.

If the sensor reader 101 determines that the strength of theelectrodynamic field received by the sensor 100 is sufficient for thesensor 100 to perform an analyte measurement, in step 1508, the sensorreader 101 may automatically convey an analyte measurement command andpower to the sensor 100. In a non-limiting embodiment, the sensor reader101 may additionally or alternatively convey other types of commands. Insome embodiments, the sensor reader 101 may convey the analytemeasurement command by modulating the electrodynamic field using theinductive element of the transceiver 103 of the sensor reader 101.

In step 1510, the sensor reader 101 may decode analyte measurementinformation conveyed from the sensor 100. The analyte measurementinformation may be received using the inductive element of thetransceiver 103 of the sensor reader 101, and the analyte measurementinformation may be decoded from modulation of the electrodynamic field.In a non-limiting embodiment, the user interface 107 of the sensorreader 101 may notify the user that the analyte measurement informationwas successfully received. In some non-limiting embodiments, theprocessor 105 of the sensor reader 101 may subsequently process thereceived analyte measurement information to determine a concentration ofan analyte, and the user interface 107 may display a value representingthe concentration of the analyte so that a user (e.g., the patient, adoctor and/or others) can read the value.

FIG. 16 illustrates an exemplary sensor control process 1600 that may beperformed by the sensor 100, which may be, for example, implanted withina living animal (e.g., a living human), in accordance with an embodimentof the present invention. The sensor control process 1600 may begin witha step 1602 of coupling the inductive element of the external reader 101and the inductive element 114 of the sensor 100 within an electrodynamicfield. The sensor 100 may use the electrodynamic field to generateoperational power. In one embodiment, the electrodynamic field mayinduce a current in inductive element 114 of sensor 100, and theinput/output (I/O) front end block 536 may convert the induced currentinto power for operating the sensor 100. In a non-limiting embodiment,rectifier 640 may be used to convert the induced current into operatingpower for the sensor 100.

In step 1604, circuitry of the sensor 100 may produce a coupling valueproportional to the strength of the coupling of the inductive element ofthe external reader 101 and the inductive element 114 of the sensor 100.In some non-limiting embodiments, the clamp/modulator 646 of the I/Ocircuit 536 may produce a coupling value (e.g., I_(couple)) proportionalto the strength of coupling based on the current induced in theinductive element 114 by the electrodynamic field. In one non-limitingembodiment, the coupling value I_(couple) proportional to the fieldstrength may be converted (e.g., by ADC 664) to a digital coupling valueproportional to the received field strength.

In some non-limiting embodiments, the coupling value may be used by thesensor 100 to determine whether the strength of the electrodynamic fieldreceived by the sensor 100 is sufficient for the sensor 100 to performan analyte measurement. For instance, in one non-limiting embodiment,the measurement controller 532 may compare the coupling value to ananalyte measurement field strength sufficiency threshold and produce anindication that the strength of the electrodynamic field received by thesensor is either sufficient or insufficient for the implanted sensor toperform the analyte measurement.

In step 1606, the sensor 100 may convey the analog or digital couplingvalue to the sensor reader 101 (e.g., by modulating the electrodynamicfield). In one embodiment, the measurement controller 532 may output thedigital coupling value to the data and control bus 654. The data andcontrol bus 654 may transfer the digital coupling value to the commanddecoder/data encoder 652, which may encode the digital coupling value.The data serializer 656 may serialize the encoded digital couplingvalue. The encoder 658 may encode the serialized digital coupling value.The clamp/modulator 646 may modulate the current flowing through theinductive element 114 (e.g., coil 220) as a function of the encodeddigital coupling value. In this way, the encoded digital coupling valuemay be conveyed by the inductive element 114 as a modulatedelectromagnetic wave. In some embodiments, the encoded digital couplingvalue conveyed by the sensor 100 may be decoded by the sensor reader101.

In step 1608, the sensor 100 may determine whether a command has beendecoded (e.g., from modulation of the electrodynamic field). In onenon-limiting embodiment, the I/O front end block 536 and I/O controller538 may convert the induced current into power for operating the sensor100 and extract and decode any received commands from the inducedcurrent. In a non-limiting embodiment, rectifier 640 may be used toconvert the induced current into operating power for the sensor 100,data extractor 642 may extract data from the current induced ininductive element 114, decoder/serializer 650 may decode and serializethe extracted data, and command decoder/data encoder 652 may decode oneor more commands from the decoded and serialized extracted data. Anydecoded commands may then be sent to measurement controller 532 via thedata and control bus 654. In some embodiments, the one or more commandsand power received by the sensor 100 may be transmitted by thetransceiver 103 of sensor reader 101.

If a command has not been decoded, the sensor control process 1600 mayreturn to step 1602. If a command has been decoded, in step 1610, thesensor 100 may execute the decoded command. For example, in oneembodiment, the sensor 100 may execute the decoded command under controlof the measurement controller 532. Example command execution processesthat may be performed by the sensor 100 in step 1610 to execute thedecoded commands are described below with reference to FIGS. 17-20.

Examples of commands that may be received and executed by the sensor 100may include analyte measurement commands, get result commands and/or gettraceability information commands. Examples of analyte measurementcommands may include measure sequence commands (i.e., commands toperform a sequence of measurements, and after finishing the sequence,transmitting the resulting measurement information), measure and savecommands (i.e., commands to perform a sequence of measurements and,after finishing the sequence, saving the resulting measurementinformation without transmitting the resulting measurement information)and/or single measurement commands (i.e., commands to perform a singlemeasurement). The single measurement commands may be commands to saveand/or transmit the measurement information resulting from the singlemeasurement. The analyte measurement commands may or may not includesetup parameters (i.e., calibration information). Measurement commandsthat do not have setup parameters may, for example, be executed usingstored setup parameters (e.g., in nonvolatile storage medium 660). Otheranalyte measurement commands, such as measurement commands to both saveand transmit the resulting measurement information, are possible. Thecommands that may be received and executed by the sensor 100 may alsoinclude commands to update the stored the setup parameters. The examplesof commands described above are not exhaustive of all commands that maybe received and executed by the sensor 100, which may be capable ofreceiving and executing one or more of the commands listed above and/orone or more other commands.

FIG. 17 illustrates an analyte measurement command execution process1700 that may be performed in step 1610 of the sensor control process1600 by the sensor 100 to execute an analyte measurement commandreceived by the sensor 100 in accordance with an embodiment of thepresent invention. In a non-limiting embodiment, the analyte measurementcommand execution process 1700 may begin with a step 1702 of determiningwhether the field strength is sufficient to execute the receivedmeasurement command. In other words, in step 1702, the sensor 100 maydetermine whether the electromagnetic field or wave that may induce acurrent in inductive element 114 is strong enough to generate sufficientoperating power for execution of the decoded measurement command, which,as described below, may include using light source 108 to irradiateindicator molecules 104. In one embodiment, step 1702 may be performedby a field strength measurement circuit, which may be part of themeasurement controller 532 or may be a separate component of thecircuitry 776 on the silicon substrate 116.

In some embodiments, if the sensor 100 determines in step 1702 that thefield strength is insufficient to execute the received measurementcommand, the analyte measurement command execution process 1700 mayproceed to a step 1704 in which the sensor 100 may convey (e.g., by wayof the input/output (I/O) front end block 536, I/O controller 538, andinductive element 114) data indicating that that the wirelessly receivedpower is insufficient to execute the received analyte measurementcommand. In some embodiments, the insufficient power data may merelyindicate that the power is insufficient, but in other embodiments, theinsufficient power data may indicate the percentage of the power neededto execute the received measurement command that is currently beingreceived.

In one embodiment, upon detection that the received power isinsufficient, the measurement controller 532 may output insufficientpower data to the data and control bus 654. The data and control bus 654may transfer the insufficient power data to the command decoder/dataencoder 652, which may encode the insufficient power data. The dataserializer 656 may serialize the encoded insufficient power data. Theencoder 658 may encode the serialized insufficient power data. Theclamp/modulator 646 may modulate the current flowing through theinductive element 114 (e.g., coil 220) as a function of the encodedinsufficient power data. In this way, the encoded insufficient powerdata may be conveyed by the inductive element 114 as a modulatedelectromagnetic wave. In some embodiments, the encoded insufficientpower data conveyed by the sensor 100 may be received by the sensorreader 101, which may display a message on user interface 107 a messageindicating that the power received by the sensor 100 is insufficientand/or the extent to which the received power is insufficient.

In some alternative embodiments, steps 1702 and 1704 are not performed,and the sensor 100 assumes that, if an analyte measurement command hasbeen decoded, the field strength is sufficient.

In step 1706 in which a measurement and conversion process may beperformed. The measurement and conversion process may, for example, beperformed by the analog interface 534 under control of the measurementcontroller 532. In one embodiment, the measurement and conversionsequence may include generating one or more analog measurements (e.g.,using one or more of temperature transducer 670, light source 108, firstphotodetector 224, second photodetector 226 and/or comparator 668) andconverting the one or more analog measurements to one or more digitalmeasurements (e.g., using ADC 664). One example of the measurementconversion process that may be performed in step 1706 is described infurther detail below with reference to FIG. 18.

At step 1708, the sensor 100 may generate measurement information inaccordance with the one or more digital measurements produced during themeasurement and conversion sequence performed in step 1706. Depending onthe one or more digital measurements produced in step 1706, themeasurement information may be indicative of the presence and/orconcentration of an analyte in a medium in which the sensor 100 isimplanted. In one embodiment, in step 1706, the measurement controller532 may receive the one or more digital measurements and generate themeasurement information.

At step 1710, the sensor 100 may determine whether the analytemeasurement information generated in step 1708 should be saved. In someembodiments, the measurement controller 532 may determine whether theanalyte measurement information should be saved. In one embodiment, themeasurement controller 532 may determine whether the measurementinformation should be saved based on the received measurement command.For example, if the analyte measurement command is a measure and savecommand or other measurement command that includes saving the resultingmeasurement information, the measurement controller 532 may determinethat the analyte measurement information generated in step 1708 shouldbe saved. Otherwise, if the analyte measurement command is a measuresequence command or other analyte measurement command that does notinclude saving the resulting measurement information, the measurementcontroller 532 may determine that the analyte measurement informationgenerated in step 1708 should not be saved.

In some embodiments, if the sensor 100 determines in step 1710 that theanalyte measurement information generated in step 1708 should be saved,the analyte measurement command execution process 1700 may proceed to astep 1712 in which the sensor 100 may save the measurement information.In one embodiment, after determining that the analyte measurementinformation generated in step 1708 should be saved, the measurementcontroller 532 may output the analyte measurement information to thedata and control bus 654, which may transfer the analyte measurementinformation to the nonvolatile storage medium 660. The nonvolatilestorage medium 660 may save the received analyte measurementinformation. In some embodiments, the measurement controller 532 mayoutput, along with the analyte measurement information, an address atwhich the measurement information is to be saved in the nonvolatilestorage medium 660. In some embodiments, the nonvolatile storage medium660 may be configured as a first-in-first-out (FIFO) orlast-in-first-out (LIFO) memory.

In some embodiments, if the sensor 100 determines in step 1710 that theanalyte measurement information generated in step 1708 should not besaved, or after saving the analyte measurement information in step 1712,the analyte measurement command execution process 1700 may proceed to astep 1714 in which the sensor 100 may determine whether the analytemeasurement information generated in step 1708 should be conveyed. Insome embodiments, the measurement controller 532 may determine whetherthe measurement information should be transmitted. In one embodiment,the measurement controller 532 may determine whether the measurementinformation should be conveyed based on the received measurementcommand. For example, if the analyte measurement command is a measuresequence command or other measurement command that includes transmittingthe resulting measurement information, the measurement controller 532may determine that the measurement information generated in step 1708should be conveyed. Otherwise, if the analyte measurement command is ameasure and save command or other measurement command that does notinclude conveying the resulting analyte measurement information, themeasurement controller 532 may determine that the analyte measurementinformation generated in step 1708 should not be conveyed.

In some embodiments, if the sensor 100 determines in step 1714 that theanalyte measurement information generated in step 1708 should beconveyed, the analyte measurement command execution process 1700 mayproceed to a step 1716 in which the sensor 100 may convey the analytemeasurement information. In one embodiment, after determining that themeasurement information generated in step 1708 should be convey, themeasurement controller 532 may output the measurement information to thedata and control bus 654. The data and control bus 654 may transfer theanalyte measurement information to the command decoder/data encoder 652,which may encode the measurement information. The data serializer 656may serialize the encoded measurement information. The encoder 658 mayencode the serialized measurement information. The clamp/modulator 646may modulate the current flowing through the inductive element 114(e.g., coil 220) as a function of the encoded measurement information.In this way, the encoded measurement information may be transmittedwirelessly by the inductive element 114 as a modulated electromagneticwave. In some embodiments, the encoded measurement informationwirelessly transmitted by the sensor 100 may be received by the sensorreader 101, which may display a value representing the concentration ofthe analyte so that a user (e.g., the patient, a doctor and/or others)can read the value.

In some embodiments, after the sensor 100 (a) conveyed insufficientpower data in step 1704, (b) determined in step 1714 that themeasurement information generated in step 1708 should not be conveyed or(c) conveyed measurement information in step 1716, the analytemeasurement command execution process 1700 that may be performed in step1610 of the sensor control process 1600 by the sensor 100 to execute ananalyte measurement command received by the sensor 100 may be completed,and, at this time, the sensor control process 1600 may return to step1602.

In some alternative embodiments, steps 1710, 1712, and 1714 are notperformed, and the sensor 100 proceeds directly to step 1710 to conveythe analyte measurement information after completing the measurementinformation generation in step 1708.

FIG. 18 illustrates a measurement and conversion process 1800, which isan example of the measurement and conversion process that may beperformed in step 1706 of the analyte measurement command executionprocess 1700, in accordance with an embodiment of the present invention.

At step 1802, the sensor 100 may load setup parameters (i.e.,calibration information) for performing one or more measurements inaccordance with the received measurement command. For example, in oneembodiment, the measurement controller 532 may load one or more setupparameters by setting up one or more components (e.g., light source 108,first photodetector 224, second photodetector 226, comparator 668 and/ortemperature transducer 534) of the analog interface 534 with the setupparameters. In some embodiments, the nonvolatile storage medium 660 maystore saved setup parameters. Further, as noted above, in someembodiments, the measurement commands may or may not include setupparameters. In a non-limiting embodiment, if the measurement commandincludes one or more setup parameters, the measurement controller 532may setup one or more components of the analog interface 534 with thesetup parameters with the one or more setup parameters included in themeasurement command. However, if the measurement command does notinclude one or more setup parameters, the measurement controller 532 mayobtain saved setup parameters stored in the nonvolatile storage medium660 and setup one or more components of the analog interface 534 withthe saved setup parameters obtained from the nonvolatile storage medium660.

At step 1804, the sensor 100 may determine whether to execute a singlemeasurement or a measurement sequence. In some embodiments, themeasurement controller 532 may make the single measurement vs.measurement sequence determination by referring to the receivedmeasurement command (i.e., is the measurement command to execute asingle measurement or to execute a measurement sequence?). For example,in some embodiments, if the measurement command is a measure sequencecommand, a measure and save command or other command for a measurementsequence, the measurement controller 532 may determine that ameasurement sequence should be executed. However, if the measurementcommand is a single measurement command, the measurement controller 532may determine that a single measurement should be executed.

In some embodiments, if the sensor 100 determines in step 1804 that ameasurement sequence should be performed, the sensor 100 may performmeasurement and conversion sequence steps 1806-1820 of measurement andconversion process 1800. However, in other embodiments, the sensor 100may perform a portion of measurement and conversion sequence steps1806-1820 and/or additional measurement and conversion sequence steps.

At step 1806, the sensor 100 may perform a light source bias measurementand conversion. For example, in some embodiments, while the light source108 is on (i.e., while the light source 108, under the control of themeasurement controller 532, is emitting excitation light and irradiatingindicator molecules 104), the analog interface 534 may generate ananalog light source bias measurement signal. In one embodiment, the ADC664 may convert the analog light source bias measurement signal to adigital light source bias measurement signal. The measurement controller532 may receive the digital light source bias measurement signal andgenerate (e.g., in step 1708 of the measurement command executionprocess 1700) the measurement information in accordance with thereceived digital light source bias measurement signal. In a non-limitingembodiment, the analog interface 534 may generate the analog lightsource bias measurement signal by sampling the voltage and the currentin the output of the current source that feeds the light source 108.

At step 1808, the sensor 100 may perform a light source-on temperaturemeasurement and conversion. For example, in some embodiments, while thelight source 108 is on (i.e., while the light source 108, under thecontrol of the measurement controller 532, is emitting excitation lightand irradiating indicator molecules 104), the analog interface 534 maygenerate a first analog temperature measurement signal indicative of atemperature of the sensor 100. In one embodiment, the temperaturetransducer 670 may generate the first analog temperature measurementsignal while the light source 108 is on. The ADC 664 may convert thefirst analog temperature measurement signal to a first digitaltemperature measurement signal. The measurement controller 532 mayreceive the first digital temperature measurement signal and generate(e.g., in step 1708 of the measurement command execution process 1700)the measurement information in accordance with the received firstdigital temperature measurement signal.

At step 1810, the sensor 100 may perform a first photodetectormeasurement and conversion. For example, in some embodiments, while thelight source 108 is on (i.e., while the light source 108, under thecontrol of the measurement controller 532, is emitting excitation lightand irradiating indicator molecules 104), the first photodetector 224may generate a first analog light measurement signal indicative of theamount of light received by the first photodetector 224 and output thefirst analog light measurement signal to the signal MUX 666. The signalMUX 666 may select the first analog light measurement signal and, theADC 664 may convert the first analog light measurement signal to a firstdigital light measurement signal. The measurement controller 532 mayreceive the first digital light measurement signal and generate (e.g.,in step 1708 of the measurement command execution process 1700) themeasurement information in accordance with the received first digitallight measurement signal.

In a non-limiting embodiment, first photodetector 224 may be a part of asignal channel, the light received by the first photodetector 224 may beemitted by indicator molecules 104 distributed throughout the indicatormembrane 106′, and the first analog light measurement signal may be anindicator measurement.

At step 1812, the sensor 100 may perform a second photodetectormeasurement and conversion. For example, in some embodiments, while thelight source 108 is on (i.e., while the light source 108, under thecontrol of the measurement controller 532 is emitting excitation lightand irradiating indicator molecules 104), the second photodetector 226may generate a second analog light measurement signal indicative of theamount of light received by the second photodetector 226 and output thesecond analog light measurement signal to the signal MUX 666. The signalMUX 666 may select the second analog light measurement signal and, theADC 664 may convert the second analog light measurement signal to asecond digital light measurement signal. The measurement controller 532may receive the second digital light measurement signal and generate(e.g., in step 1708 of the measurement command execution process 1700)the measurement information in accordance with the received seconddigital light measurement signal.

In a non-limiting embodiment, second photodetector 226 may be a part ofa reference channel, the light received by the second photodetector 226may be emitted by indicator molecules 104 distributed throughout thereference membrane 106″, and the second analog light measurement signalmay be a reference measurement.

At step 1814, the sensor 100 may perform a difference measurement andconversion. For example, in some embodiments, while the light source 108is on (i.e., while the light source 108, under the control of themeasurement controller 532, is emitting excitation light and irradiatingindicator molecules 104), (i) the first photodetector 224 may generate afirst analog light measurement signal indicative of the amount of lightreceived by the first photodetector 224, and (ii) the secondphotodetector 226 may generate a second analog light measurement signalindicative of the amount of light received by the second photodetector226. The comparator 668 may receive the first and second analog lightmeasurement signals and generate an analog light difference measurementsignal indicative of a difference between the first and second analoglight measurement signals. The comparator 668 may output the analoglight difference measurement signal to the signal MUX 666. The signalMUX 666 may select the analog light difference measurement signal and,the ADC 664 may convert the analog light difference measurement signalto a digital light difference measurement signal. The measurementcontroller 532 may receive the digital light difference measurementsignal and generate (e.g., in step 1708 of the measurement commandexecution process 1700) the measurement information in accordance withthe received digital light difference measurement signal.

In a non-limiting embodiment, first photodetector 224 may be a part of asignal channel, second photodetector 226 may be a part of a referencechannel, and the analog light difference measurement signal may beindicative of the difference in light emitted by (a) indicator molecules104 distributed throughout indicator membrane 106′ and affected by theconcentration of an analyte in the medium in which sensor 100 isimplanted, and (b) indicator molecules 104 distributed throughoutreference membrane 106″ and unaffected by the concentration of theanalyte in the medium in which sensor 100 is implanted.

At step 1816, the sensor 100 may perform a second photodetector ambientmeasurement and conversion. For example, in some embodiments, while thelight source 108 is off (i.e., while the light source 108, under thecontrol of the measurement controller 532 is not emitting light), thesecond photodetector 226 may generate a second analog ambient lightmeasurement signal indicative of the amount of light received by thesecond photodetector 226 and output the second analog ambient lightmeasurement signal to the signal MUX 666. The signal MUX 666 may selectthe second analog ambient light measurement signal and, the ADC 664 mayconvert the second analog ambient light measurement signal to a seconddigital ambient light measurement signal. The measurement controller 532may receive the second digital ambient light measurement signal andgenerate (e.g., in step 1708 of the measurement command executionprocess 1700) the measurement information in accordance with thereceived second digital ambient light measurement signal.

In a non-limiting embodiment, second photodetector 226 may be a part ofa reference channel, the light received by the second photodetector 226may be emitted by indicator molecules 104 distributed throughout thereference membrane 106″, and the second analog ambient light measurementsignal may be an ambient reference measurement.

At step 1818, the sensor 100 may perform a first photodetector ambientmeasurement and conversion. For example, in some embodiments, while thelight source 108 is off (i.e., while the light source 108, under thecontrol of the measurement controller 532, is not emitting light), thefirst photodetector 224 may generate a first analog ambient lightmeasurement signal indicative of the amount of light received by thefirst photodetector 224 and output the first analog ambient lightmeasurement signal to the signal MUX 666. The signal MUX 666 may selectthe first analog ambient light measurement signal and, the ADC 664 mayconvert the first analog ambient light measurement signal to a firstdigital ambient light measurement signal. The measurement controller 532may receive the first digital ambient light measurement signal andgenerate (e.g., in step 1708 of the measurement command executionprocess 1700) the measurement information in accordance with thereceived first digital ambient light measurement signal.

In a non-limiting embodiment, first photodetector 224 may be a part of asignal channel, the light received by the first photodetector 224 may beemitted by indicator molecules 104 distributed throughout the indicatormembrane 106′, and the first analog ambient light measurement signal maybe an ambient indicator measurement.

At step 1820, the sensor 100 may perform a light source-off temperaturemeasurement and conversion. For example, in some embodiments, while thelight source 108 is off (i.e., while the light source 108, under thecontrol of the measurement controller 532, is not emitting light), theanalog interface 534 may generate a second analog temperaturemeasurement signal indicative of a temperature of the sensor 100. In oneembodiment, the temperature transducer 670 may generate the secondanalog temperature measurement signal while the light source 108 is off.The ADC 664 may convert the second analog temperature measurement signalto a second digital temperature measurement signal. The measurementcontroller 532 may receive the second digital temperature measurementsignal and generate (e.g., in step 1708 of the measurement commandexecution process 1700) the measurement information in accordance withthe received second digital temperature measurement signal.

Accordingly, in an embodiment in which sequence steps 1806-1820 ofmeasurement and conversion process 1800 are performed, the measurementcontroller 532 may generate measurement information in accordance with(i) the first digital temperature measurement signal, (ii) the firstdigital light measurement signal, (iii) the second digital lightmeasurement signal, (iv) the digital light difference measurementsignal, (v) the second digital temperature measurement signal, (vi) thefirst digital ambient light measurement signal and (vii) the seconddigital ambient light measurement signal. In a non-limiting embodiment,the calculation of the concentration of the analyte performed by themeasurement controller 532 of sensor 100 and/or sensor reader 101 mayinclude subtracting the digital ambient light signals from thecorresponding digital light measurement signals. The calculation of theconcentration of the analyte may also include error detection. In someembodiments, the measurement controller 532 may incorporate methods forattenuating the effects of ambient light, such as, for example, thosedescribed in U.S. Pat. No. 7,227,156, which is incorporated herein byreference in its entirety. In some embodiments, the measurementcontroller 532 may generate measurement information that merelycomprises the digital measurement signals received from the analoginterface 534. However, in other embodiments, the measurement controller532 may process the digital signals received from the analog interface534 and determine (i.e., calculate and/or estimate) the concentration ofan analyte in the medium in which the sensor 100 is implanted, and themeasurement information may, additionally or alternatively, include thedetermined concentration.

In some embodiments, if the sensor 100 determines in step 1804 that ameasurement sequence should be performed, the measurement and conversionprocess 1800 may proceed to a step 1822 in which a single measurementand conversion is performed. In some embodiments, based on themeasurement command received, the single measurement and conversionperformed in step 1822 may be any one of the measurements andconversions performed in steps 1806-1820. Accordingly, in an examplewhere step 1822 of the measurement and conversion process 1800 isperformed, the measurement controller 532 may receive only one digitalmeasurement signal, and the measurement information generated by themeasurement controller 532 (e.g., in step 1708 of the measurementcommand execution process 1700) may, in one embodiment, simply be theone digital measurement signal received by the measurement controller.

In some embodiments, light source 108 may be turned on before executionof step 1806 and not turned off until after execution of step 1814.However, this is not required. For example, in other embodiments, thelight source 108 may be turned on during measurement portions of steps1806-1814 and turned off during the conversion portions of steps1806-1814.

Furthermore, although FIG. 18 illustrates one possible sequence of themeasurement and conversion process 1800, it is not necessary that steps1806-1820 of the measurement and conversion process 1800 be performed inany particular sequence. For example, in one alternative embodiment,light measurement and conversion steps 1806-1814 may be performed in adifferent order (e.g., 1808, 1812, 1814, 1810, 1806), and/or ambientlight measurement and conversion steps 1816-1820 may be performed in adifferent order (e.g., 1818, 1820, 1816). In some embodiments, the lightsource on temperature measurement may be used to provide an error flagin each individual measurement (e.g., by using a comparator to comparingthe light source on temperature measurement to threshold value). Inanother alternative embodiment, ambient light measurement and conversionsteps 1816-1820 may be performed before light measurement and conversionsteps 1806-1814. In still another alternative embodiment, steps1806-1820 of the measurement and conversion process 1800 may beperformed in a sequence in which all of the steps of one of lightmeasurement and conversion steps 1806-1814 and ambient light measurementand conversion steps 1816-1820 are completed before one or more steps ofthe other are executed (e.g., in one embodiment, steps 1806-1820 may beperformed in the sequence 1806, 1808, 1810, 1818, 1816, 1812, 1814,1820).

FIGS. 21A and 21B illustrates the timing of an exemplary embodiment ofthe measurement and conversion process 1800 described with reference toFIG. 18.

FIG. 19 illustrates a get result command execution process 1900 that maybe performed in step 1610 of the sensor control process 1600 by thesensor 100 to execute a get result command received by the sensor 100 inaccordance with an embodiment of the present invention. The measurementcommand execution process 1900 may begin with a step 1902 of retrievingsaved measurement information. For example, retrieved measurementinformation may be saved during step 1712 of the analyte measurementcommand execution process 1700 shown in FIG. 17. In some embodiments,measurement information is saved in the nonvolatile storage medium 660.In response to a request from the measurement controller 532, thenonvolatile storage medium 660 may output saved measurement informationto the data and control bus 654. In some embodiments, the data andcontrol bus 654 may transfer the retrieved measurement information tothe measurement controller 532. However, in alternative embodiments, thedata and control bus 654 may transfer the retrieved measurementinformation to the command decoder/data encoder 652 without firsttransferring the retrieved measurement information to the measurementcontroller 532.

In some embodiments, the nonvolatile storage medium 660 may output tothe data and control bus 654 the measurement information most recentlysaved to the nonvolatile storage medium 660. In some alternativeembodiments, the nonvolatile storage medium 660 may output to the dataand control bus 654 the oldest measurement information most saved to thenonvolatile storage medium 660. In other alternative embodiments, thenonvolatile storage medium 660 may output to the data and control bus654 the measurement information specifically requested by themeasurement controller 532 (e.g., by an address sent to the nonvolatilestorage medium 660 with a read request).

After the saved measurement information is retrieved, the get resultcommand execution process 1900 may proceed to a step 1904 in which thesensor 100 may convey the retrieved measurement information. In oneembodiment, the measurement controller 532 may output the retrievedmeasurement information to the data and control bus 654. The data andcontrol bus 654 may transfer the measurement information to the commanddecoder/data encoder 652, which may encode the retrieved measurementinformation. The data serializer 656 may serialize the encoded retrievedmeasurement information. The encoder 658 may encode the serializedretrieved measurement information. The clamp/modulator 646 may modulatethe current flowing through the inductive element 114 (e.g., coil 220)as a function of the encoded retrieved measurement information. In thisway, the encoded retrieved measurement information may be conveyed bythe inductive element 114 as a modulated electromagnetic wave. In someembodiments, the encoded retrieved measurement information conveyed bythe sensor 100 may be received by the sensor reader 1500.

FIG. 20 illustrates a get identification information command executionprocess 2000 that may be performed in step 1610 of the sensor controlprocess 1600 by the sensor 100 to execute a get identificationinformation command received by the sensor 100 in accordance with anembodiment of the present invention. The get identification informationcommand execution process 2000 may begin with a step 2002 of retrievingstored identification information. In some embodiments, identificationinformation is stored in the nonvolatile storage medium 660. In responseto a request from the measurement controller 532, the nonvolatilestorage medium 660 may output identification information to the data andcontrol bus 654. In some embodiments, the data and control bus 654 maytransfer the retrieved identification information to the measurementcontroller 532. However, in alternative embodiments, the data andcontrol bus 654 may transfer the retrieved identification information tothe command decoder/data encoder 652 without first transferring theretrieved identification information to the measurement controller 532.

After the stored identification information is retrieved, the getidentification information command execution process 2000 may proceed toa step 2004 in which the sensor 100 may convey the retrievedidentification information. In one embodiment, the measurementcontroller 532 may output the retrieved identification information tothe data and control bus 654. The data and control bus 654 may transferthe identification information to the command decoder/data encoder 652,which may encode the identification information. The data serializer 656may serialize the encoded identification information. The encoder 658may encode the serialized identification information. Theclamp/modulator 646 may modulate the current flowing through theinductive element 114 (e.g., coil 220) as a function of the encodedretrieved identification information. In this way, the encodedidentification information may be conveyed by the inductive element 114as a modulated electromagnetic wave. In some embodiments, the encodedidentification information conveyed by the sensor 100 may be received bythe sensor reader 101.

The sensor 100 may be capable of executing other commands received bythe sensor. For example, the sensor 100 may perform a setup parameterupdate execution process that may be performed in step 1610 of thesensor control process 1600 by the sensor 100 to execute a command toupdate setup parameters. In some embodiments, the setup parameter updateexecution process may replace one or more setup parameters (i.e.,initialization information) stored in the nonvolatile storage medium660. In one embodiment, upon receiving a command to update setupparameters, the measurement controller 532 may output one or more setupparameters received with the command to the data and control bus 654,which may transfer the setup parameter(s) to the nonvolatile storagemedium 660. The nonvolatile storage medium 660 may store the receivedsetup parameter(s). In a non-limiting embodiment, the received setupparameter(s) may replace one or more setup parameters previously storedin the nonvolatile storage medium 660.

FIG. 22 illustrates an alternative sensor control process 2200 that maybe performed by the sensor 100, which may be, for example, implantedwithin a living animal (e.g., a living human), in accordance with anembodiment of the present invention. The sensor control process 2200 maybegin with a step 2202 of coupling the inductive element of the externalreader 101 and the inductive element 114 of the sensor 100 within anelectrodynamic field. The sensor 100 may use the electrodynamic field togenerate operational power. In one embodiment, the electrodynamic fieldmay be received using the inductive element 114 of the sensor 100. Theelectrodynamic field may induce a current in inductive element 114, andthe input/output (I/O) front end block 536 may convert the inducedcurrent into power for operating the sensor 100. In a non-limitingembodiment, rectifier 640 may be used to convert the induced currentinto operating power for the sensor 100.

In step 2204, circuitry of the sensor 100 may produce a coupling valueproportional to the strength of the coupling of the inductive element ofthe external reader 101 and the inductive element 114 of the sensor 100.In some non-limiting embodiments, the clamp/modulator 646 of the I/Ocircuit 536 may produce a coupling value (e.g., I_(couple)) proportionalto the received field strength based on the current induced in theinductive element 114 by the electrodynamic field. In one non-limitingembodiment, the coupling value proportional to the field strength may beconverted (e.g., by ADC 664) to a digital coupling value proportional tothe received field strength.

In step 2206, the reader may use the analog and/or digital couplingvalue to determine whether the strength of the electrodynamic fieldreceived by the sensor 100 is sufficient for the sensor 100 to performan analyte measurement. For instance, in one non-limiting embodiment,the measurement controller 532 may compare the digital coupling value toan analyte measurement field strength sufficiency threshold and producean indication that the strength of the electrodynamic field received bythe sensor is either sufficient or insufficient for the implanted sensorto perform the analyte measurement.

If the sensor 100 determines that the strength of the electrodynamicfield received by the sensor 100 is insufficient, in step 2208, thesensor 100 may convey the field strength data including the analog ordigital coupling value and/or the indication that the strength of theelectrodynamic field received by the sensor is either sufficient orinsufficient to the external sensor reader 101 (e.g., by modulating theelectrodynamic field based on the field strength data). In oneembodiment, the measurement controller 532 may output the field strengthdata to the data and control bus 654. The data and control bus 654 maytransfer the field strength data to the command decoder/data encoder652, which may encode the field strength data. The data serializer 656may serialize the encoded field strength data. The encoder 658 mayencode the serialized field strength data. The clamp/modulator 646 maymodulate the current flowing through the inductive element 114 (e.g.,coil 220) as a function of the encoded field strength data. In this way,the encoded field strength data may be conveyed by the inductive element114 as a modulated electromagnetic wave. In some embodiments, theencoded field strength data conveyed by the sensor 100 may be receivedby the sensor reader 101.

If the sensor 100 determines that the strength of the electrodynamicfield received by the sensor 100 is sufficient, in step 2210, the sensor100 may automatically execute an analyte measurement sequence (e.g., theanalyte measurement command execution process 1700 shown in FIG. 17) andgenerate analyte measurement information.

In step 2212, the sensor 100 may the sensor 100 may convey the analytemeasurement information to the sensor reader 101 using the inductiveelement 114. In one embodiment, the measurement controller 532 mayoutput the analyte measurement information to the data and control bus654. The data and control bus 654 may transfer the analyte measurementinformation to the command decoder/data encoder 652, which may encodethe analyte measurement information. The data serializer 656 mayserialize the encoded analyte measurement information. The encoder 658may encode the serialized field strength data. The clamp/modulator 646may modulate the current flowing through the inductive element 114(e.g., coil 220) as a function of the encoded analyte measurementinformation. In this way, the encoded analyte measurement informationmay be conveyed by the inductive element 114 as a modulatedelectromagnetic wave. In some embodiments, the encoded analytemeasurement information conveyed by the sensor 100 may be received bythe sensor reader 101.

In another embodiment, the field strength system may be utilized as aconvenient sensor locator to be used when physicians wish to remove thesensor 100 following its useful life in vivo. The sensor 100 is notvisible when implanted in the subcutaneous space, and it is not alwayseasy to palpate under the skin for some users that may have more adiposetissue in the space. The field strength trigger system may be configuredas a pinpoint locator function joined with a set marking on the readercase to provide physicians with the ability use the reader to place areference mark on the skin for use in making a precise incision forremoving the sensor 100 without having to guess the exact location ofthe implant and where the incision is to be made for most efficientremoval.

Embodiments of the present invention have been fully described abovewith reference to the drawing figures. Although the invention has beendescribed based upon these preferred embodiments, it would be apparentto those of skill in the art that certain modifications, variations, andalternative constructions could be made to the described embodimentswithin the spirit and scope of the invention. For example, while theinvention has been described with reference to a case or reader coupledto a smartphone, the sensor reader can be an independent box or a keyfob that communicates to a smartphone or computer through Bluetooth or aphysical cable connection. In addition, circuitry of the sensor 100 andreader 101 may be implemented in hardware, software, or a combination ofhardware or software. The software may be implemented as computerexecutable instructions that, when executed by a processor, cause theprocessor to perform one or more functions.

We claim:
 1. A reader comprising: a transceiver including a first inductive element configured to couple with a second inductive element within an electrodynamic field, wherein the transceiver is configured to receive analyte measurement information from the second inductive element by detecting modulations in the electrodynamic field; circuitry configured to receive the analyte measurement information from the transceiver and decode the analyte measurement information; and a user interface configured to generate a notification indicating that the analyte measurement information was successfully received from the second inductive element if the analyte measurement information was successfully received.
 2. The reader of claim 1, wherein the circuitry is further configured to calculate an analyte concentration using at least the decoded analyte measurement information.
 3. The reader of claim 1, wherein the analyte measurement information includes a calculated analyte concentration.
 4. The reader of claim 1, wherein the circuitry is further configured to: determine whether the analyte measurement information was successfully received from the second inductive element; and if the analyte measurement information was successfully received, cause the user interface to generate the notification indicating that the analyte measurement information was successfully received from the second inductive element.
 5. The reader of claim 1, wherein the second inductive element is an inductive element of a sensor.
 6. The reader of claim 5, wherein the circuitry is further configured to: generate field strength data indicative of the strength of coupling of the first and second inductive elements within the electrodynamic field; determine, based on the field strength data, whether the strength of the coupling of the first and second inductive elements is sufficient for the sensor to perform an analyte measurement and convey the results of the analyte measurement to the reader; if the strength of the coupling of the first and second inductive elements is determined to be insufficient, repeat the generating and determining steps; and if the strength of the coupling of the first and second inductive elements is determined to be sufficient, trigger an analyte measurement by the sensor and conveyance of the results of the analyte measurement to the reader, wherein the triggering comprises conveying an analyte measurement command to the sensor via the first inductive element.
 7. The reader of claim 1, wherein the first inductive element is a coil.
 8. The reader of claim 1, wherein the circuitry is a processor.
 9. A method comprising: coupling a first inductive element of a transceiver with a second inductive element within an electrodynamic field; using the transceiver to receive analyte measurement information from the second inductive element by detecting modulations in the electrodynamic field; using circuitry to receive the analyte measurement information from the transceiver; using the circuitry to decode the analyte measurement information; and using a user interface to generate a notification indicating that the analyte measurement information was successfully received from the second inductive element if the analyte measurement information was successfully received.
 10. The method of claim 9, further comprising using the circuitry to calculate an analyte concentration using at least the decoded analyte measurement information.
 11. The method of claim 9, wherein the analyte measurement information includes a calculated analyte concentration.
 12. The method of claim 9, further comprising: using the circuitry to determine that the analyte measurement information was successfully received from the second inductive element; and using the circuitry to cause the user interface to generate the notification indicating that the analyte measurement information was successfully received from the second inductive element.
 13. The method of claim 9, wherein the second inductive element is an inductive element of a sensor, and the method further comprises using the circuitry to: generate field strength data indicative of the strength of coupling of the first and second inductive elements within the electrodynamic field; determine, based on the field strength data, whether the strength of the coupling of the first and second inductive elements is sufficient for the sensor to perform an analyte measurement and convey the results of the analyte measurement to the reader.
 14. The method of claim 13, further comprising: determining that the strength of the coupling of the first and second inductive elements is insufficient; and using the circuitry to repeat the generating step and the determining whether the strength of the coupling of the first and second inductive elements is sufficient step.
 15. The method of claim 13, further comprising: determining that the strength of the coupling of the first and second inductive elements is sufficient; and using the circuitry to trigger an analyte measurement by the sensor and conveyance of the results of the analyte measurement to the reader, wherein the triggering comprises conveying an analyte measurement command to the sensor via the first inductive element.
 16. A system comprising: a sensor including a first inductive element; and a reader including: a transceiver including a second inductive element configured to couple with the first inductive element of the sensor within an electrodynamic field, wherein the transceiver is configured to receive analyte measurement information from the first inductive element by detecting modulations in the electrodynamic field; circuitry configured to receive the analyte measurement information from the transceiver and decode the analyte measurement information; and a user interface configured to generate a notification indicating that the analyte measurement information was successfully received from the sensor if the analyte measurement information was successfully received.
 17. The system of claim 16, wherein the sensor further comprises a light source, indicator molecules, and a photodetector.
 18. The system of claim 16, wherein the circuitry of the reader is further configured to calculate an analyte concentration using at least the decoded analyte measurement information.
 19. The system of claim 16, wherein the analyte measurement information includes a calculated analyte concentration.
 20. The system of claim 16, wherein the circuitry of the reader is further configured to: determine whether the analyte measurement information was successfully received from the first inductive element of the sensor; and if the analyte measurement information was successfully received, cause the user interface to generate the notification indicating that the analyte measurement information was successfully received from the sensor. 